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Design and Analysis of a Five-Phase Permanent-Magnet Synchronous Motor for Fault-Tolerant Drive

Muhammad Haseeb Iftikhar, Byung-Gun Park, Ji‐Won Kim

2021Energies23 citationsDOIOpen Access PDF

Abstract

Reliability is a fundamental requirement in electric propulsion systems, involving a particular approach in studies on system failure probabilities. An intrinsic improvement to the propulsion system involves introducing robust architectures such as fault-tolerant motor drives to these systems. Considering the potential for hardware failures, a fault-tolerant design approach will achieve reliability objectives without recourse to optimized redundancy or over-sizing the system. Provisions for planned degraded modes of operation are designed to operate the motor in fault-tolerant mode, which makes them different from the pure design redundancy approach. This article presents how a five-phase permanent-magnet synchronous motor operates under one- or two-phase faults, and how the system reconfigures post-fault motor currents to meet the torque and speed requirement of reliable operation that meets the requirements of an electric propulsion system.

Topics & Concepts

Fault tolerancePropulsionRedundancy (engineering)SizingElectrically powered spacecraft propulsionSynchronous motorTorqueEngineeringMotor driveControl engineeringAutomotive engineeringComputer scienceReliability engineeringElectrical engineeringMechanical engineeringAerospace engineeringPhysicsThermodynamicsVisual artsArtMultilevel Inverters and ConvertersElectric Motor Design and AnalysisAdvanced Battery Technologies Research
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